In today's complex world of GPS, glass cockpits, and flight management
systems, sometimes a simple rule of thumb or memory aid is still the best way for a
pilot to avoid an accident. After a lot of work, I think N.I.G.H.T. is one such flight
planning aid pilots should use before every night flight.

Night flight has certain inherent risks. After a friend was killed in a nighttime accident,
I started reviewing all the information I could find relating to night flying accidents,
including various safety recommendations. In summarizing my research, I
think the five most important questions a pilot can ask or review before a
night flight are contained in the acronym N.I.G.H.T.
Each letter asks a question or relates to a topic that I think a pilot
should consider before every night flight.

The five simple letters stand for five critical issues that address important
operational issues, potential hazards, or physical limitations - topics
unique to night flight.

NOTAMS - Did I Check Local NOTAMs?

When it comes to NOTAMs, you don't know what you don't know! Every prudent pilot
obtains a full briefing from a Flight Service Station or by using a DUAT session to
ensure they have all the information necessary to conduct a safe flight. An important
part of that briefing will be NOTAMs.

But do you really know what you're getting ... or not getting? Often, the
answer is "No!"

NOTAMs are classified into three categories:

NOTAM (D) or distant

NOTAM (L) or local; and

Flight Data Center (FDC) NOTAMs.

If your flight is to a distant airport, the NOTAMs you receive typically will include
information on navigational facilities, frequency changes, and regulatory amendments.
But it will not include information contained in local NOTAMs. For instance, local
NOTAMs include such information as runway or taxiway closures and airport lighting outages.
A total or partial outage of a Visual Approach Slope Indicator (VASI) or
Runway End Identifier Lights (REIL) system also will be reported as a local NOTAM.

The only way to obtain a local NOTAM for your destination airport is to call the
FSS responsible (see Airport/Facility Directory) or to call the
airport manager.

Illusions - Have I Considered Them?

Many different illusions can be experienced in flight; some can lead to spatial
disorientation while others can lead to landing errors. Illusions rank among the most
common factors cited as contributing to fatal accidents.

Illusions Leading to Spatial Disorientation

Various complex motions and forces and certain visual scenes encountered in flight
can create illusions of motion and position. Spatial disorientation from these
illusions can be prevented only by visual reference to reliable, fixed points on
the ground or to flight instruments. For more information on the illusions such as:

Coriolis illusion

Graveyard spiral

Somatogravic illusion

False horizon

Autokinesis

Elevator illusion

Inversion illusion

Refer to Chapter 8 of the Aeronautical Information Manual (AIM).

Illusions Leading to Landing Errors

Various surface features and atmospheric conditions encountered in landing can create
illusions of incorrect height above and distance from the runway threshold. Landing errors
from these illusions can be prevented by anticipating them during approaches and by using
an electronic glide slope or VASI system when available. The most common illusions leading
to landing errors are:

Runway width illusion. A narrower than usual runway can create the illusion
that the aircraft is at a higher altitude than it actually is. The pilot who does not
recognize this illusion will likely fly a lower approach, with the risk of striking
objects along the approach path or landing short. A wider than usual runway can have the
opposite effect, with the risk of overshooting the runway.

Runway and terrain slopes illusion. An up-sloping runway, up-sloping terrain,
or both, can create the illusion that the aircraft is at a higher altitude than it is
actually is. The pilot who does not recognize this illusion will actually fly a lower
than normal approach. A down-sloping runway, down-sloping approach terrain, or both, can
have the opposite effect.

Featureless terrain illusion. An absence of ground features, as when landing
over water, darkened areas, and terrain made featureless by snow, can create the illusion
that the aircraft is at a higher attitude than it actually is. The pilot who does not
recognize this illusion will fly a lower approach.

Atmospheric illusions. Rain on the windscreen can create the illusion of
greater height, and atmospheric haze can create the illusion of being at a greater
distance from the runway.

Ground lighting illusions. Bright runway and approach light systems,
especially when few lights illuminate the surrounding terrain, may cause the illusion
of less distance from the runway. A pilot who does not recognize this will fly a
higher approach. Conversely, the pilot over-flying terrain which has few lights to
provide height cues may make a lower than normal approach.

Glideslope - Is One Available?

Check to see if a visual or electronic glide slope is available before departing to your
destination. Although visual glide slope indicators are installed at most airports, it is
important to note that they may be installed at only one runway end. Also, there are many
variations. Some of the not-so-common indicators include the Tricolor System, Pulsating
System,Alignment of Element System, and the Three-bar VASI.

Tri-color System. Tri-color visual approach slope indicators normally
consist of a single light unit projecting a three-color visual approach path into
the final approach area of the runway upon which the indicator is installed.
The below glide path indication is red, the above glide path indication is amber,
and the on glide path indicator is green. These types of indicators have a useful
range of approximately one-half to one mile during the day and up to five miles at night.
Note: Since the tri-color VASI consists of a single light source which could
possibly be confused with other light sources, pilots should exercise care to properly
locate and identify the light signal.

Pulsating Systems. Pulsating visual approach slope indicators normally
consist of a single light unit projecting a two color visual approach into the final
approach area of the runway upon which the indicator is installed. The on-glide path
indication is a steady white light. The slightly below-glide path indication is a steady
red light. If the aircraft descends further below the glide path, the red light
starts to pulsate. The above glide path is a pulsating white light. The pulsating rate
increases, as the aircraft gets further above or below the desired glide slope. The useful
range of this system is about four miles during the day and up to ten miles at night.

Alignment of Element Systems. Alignment of elements systems are installed on
some small general aviation airports and are a low-cost system consisting of painted panels,
normally black, white or fluorescent orange. Some of these are lighted for night use. The
useful range of these systems is about three-quarters of a mile.

Three-bar VASI. Three bar VASI installations provide two visual glide paths.
The lower glide path is normally set at three degrees while the upper glide path, provided
by the middle and far bars, is normally 1/4 degree higher. The higher glide path is intended
for use only by high cockpit aircraft (Boeing 747,DC10) to provide a sufficient threshold
crossing height.

Note: Although normal glide path angles are three degrees, angles at some
locations may be as high as 4.5 degrees to give proper obstacle clearance. Pilots
of high performance aircraft are cautioned that use of VASI angles in excess of 3.5
degrees may cause an increase in runway length required for landing and rollout.

How Do I Control Lighting Systems?

Operation of airport lighting systems (rotating beacons, approach lights, VASI, REIL,
taxiway lights and runway lights) may be controlled by the control tower, a Flight
Service Station (FSS) or by the pilot with radio control. On runways with both approach
lighting and runway lighting (runway edge lights, taxiway lights, etc.) systems, the approach
lighting system takes precedence for air to ground radio control over the runway lighting
system.

Note: Although the CTAF is used to activate lights at many airports, other
frequencies may also be used. The appropriate frequency for activating the lights on the
airport can only be found in the Airport/Facility Directory or on a standard instrument
approach procedures publication. It is not identified on the sectional charts.

Terrain - How Do I Avoid It?

Avoiding terrain at night is easier if altitudes shown on VFR and IFR charts are used as
part of your preflight planning.

VFR Charts show Maximum Elevation Figures (MEFs). The Maximum Elevation
Figures shown in quadrangles bounded by ticked lines of latitude and longitude are
represented in THOUSANDS and HUNDREDS of feet above mean sea level. MEFs are determined by
rounding the highest known elevation within the quadrangle, including terrain and obstruction
(trees, towers, antennas, etc) to the next 100 foot level. These altitudes are then adjusted
upward between 100 to 300 feet. Recognize that this practice could give as little as 101 feet
of obstacle clearance.

Adrian A. Eichhorn is 7,000-hour pilot who formerly worked for the FAA.
He is a volunteer Aviation Safety Counselor, a NAFI Master CFI, and the 2001
National Safety Counselor of the Year. He also holds an Airframe & Powerplant
certificate with inspection authorization (IA).

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